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1
- Pr
- For
Hans Brem
Kurzfassun
Schmelzdruck
Sie gelangen
verfestigen si
Trocknungsei
Gegenüber de
sowie Brandg
Druckqualität
Wesentlich ve
Verdruckbark
Gesundheits-
Darüber hina
Überbrücken
Diese erfolgre
jedoch wegen
Weiterarbeit
Abstract
Fusible inks
resulting high
fused state, s
supply or equ
In contrast to
Fusible ink is
Dot enlargem
requirements
safety are me
Furthermore plate depend
It were not a
stopped and
The hitherto
rogres
Sch
rtschr
mer
ng
kfarben sind u
in fester Form
ich sofort auf d
inrichtung.
em traditionel
gefahr sind geg
t hängt wenig
erringert ist da
keit, zur Punkt
und Umwelts
aus ist ein Pote
der Unterschi
eiche Entwick
n irgendwelch
publiziert.
have been de
h quality prin
olidify at once
uipment.
o traditional an
s much easier
ment is reduc
s of ink proper
et or exceeded
a general prident printing p
any technical
abandoned wi
yielded develo
Fusi
ss for
hmelz
ritte f
unter geringen
m in den Druck
dem Bedrucks
llen und aktue
genstandslos.
ger von den Be
as Tonen im w
twiedergabe, z
schutz werden
ential für einen
iede zwischen
lungsarbeit ist
her technischer
eveloped at s
nts. They are f
e on the substr
nd actual prin
and cleaner to
ced. Basically
rties like runn
d.
int technologyprocesses.
development
ithout comple
opment results
ible In
Offse
zdruc
für de
n Kosten entwi
kprozess, werd
toff und verla
ellen Drucken
Schmelzdruck
edruckbarkeits
wasserlosen Of
zur mechanisc
n eingehalten
n allgemeinen
den gegenwä
t nur aus äuße
r Probleme. Di
small expense
fed into the p
rate, and leave
nting, by fusibl
o be handled.
very reduced
ning, dot rend
y progress pot
drawbacks bu
tion.
s are disclosed
nk
et Pri
ckfarb
en Off
ickelt worden,
den mäßig erw
assen die Masc
wird mit Schm
kfarbe ist viel e
seigenschaften
ffsetdruck. Die
chen Festigkeit
oder übertroff
n Fortschritt de
ärtigen druckp
eren Gründen
ie bis dahin er
s which do r
press in solid f
e the press rea
le ink much en
Its high print
d is the scum
ering, ink-film
tential is notic
ut only extern
d for a reward
Copyrigh
nting
be
fsetdr
, die im tempe
wärmt, durchla
chine fertig ("t
melzdruckfarb
einfacher und
n des Papiers a
e weiteren Dru
t der Druckfar
fen.
er Druck-Tech
lattenbedingte
unvollendet a
rzielten Ergebn
really print in
form, are mo
adily solidified
nergy is saved
t quality is less
mming tenden
m strain resista
ceable, e.g. br
al reasons by
ing continuati
t © Technisch
g -
ruck -
erierten Offset
aufen den Dru
trocken"), und
en viel Energie
sauberer zu h
b. Der Punktzu
uckfarben-Erfo
benschicht, zu
nologie bemer
en Druckverfah
bgebrochen un
nisse werden h
temperature
oderately heat
d (“dry”), and
d, and VOC and
s dependent o
ncy in waterle
ance, deinkabi
ridging the di
which this ve
ion.
he Universität
-
zu Qualitätsd
uckvorgang ge
d das ohne Ene
ie gespart, und
handhaben. Ih
zuwachs ist ver
ordernisse wie
ur Deinkbarke
rkenswert, so
ahren.
und aufgegeben
hier für eine a
adjusted offs
ted for passing
this without a
nd fire hazards
on paper print
ess offset pri
ility, health an
ifferences betw
ery promising
Darmstadt, 20
drucken führen
schmolzen,
ergiezufuhr od
d Emissionen
re hohe
rringert.
die zur
it sowie zum
zum
n worden, nich
ussichtsreiche
set printing, t
g the ink train
any drying ene
s are meaningl
ability propert
inting. The ot
nd environme
ween the exist
project had b
011
n.
der
ht
thus
n in
ergy
less.
ties.
ther
ntal
tent
been
2 Copyright © Technische Universität Darmstadt, 2011
1 Introduction
Proposals for fusible inks have been reported in the literature at least since the thirties. They were mainly directed to gravure
(besides to flexo and to non impact printing). Their only purpose was avoiding the volatile solvents and the expenses of
handling them according to their risks. - Crucial step of gravure printing is emptying the gravure cylinder cells. For it, a
certain and not too small cell volume and a low ink viscosity are a mandatory exigence. And this not too small ink volume
must shrink after its transfer for forming an ink-like thin and fast film. These conditions are ideally met by the application of
volatile solvents, but hardly or not at all by fusible inks. For them, a non-volatile diluting agent ("wax") (see item 4.3.3) is
needed. With it, the low viscosity necessary can only be attained by a wax surplus plus a high temperature. The former
inhibits shrinking and mechanical fastness in ink film forming. The latter requires intolerably hot gravure and impression
cylinders. Therefore, without an ink which combines really low viscosity with sufficient film fastness, and without a less
voluminous ink transfer, it could not succeed since June 1937, the first date, I know, of a related patent application. That are
three quarters of a century with repeated attempts. Five significant patents on gravure are listed in item 6. Related literature
on offset could not be found, also not against my patent when challenged up to the supreme instance.
My approach is different. Its main purpose was replacing the heatset offset process (see 3.1 and 7) for printing on glazed or
coated papers. Additional advantages arose in the development course. - Offset became feasible since the implementation of
short inking units, temperature controlled printing, and the extrusion technique. For offset, higher melt viscosities are
necessary, thus enabling lower press temperatures, more scope for formulating inks, mechanically faster ink films, and
cheaper development work. With offset, fusible ink can be easier introduced to business. It can begin with single and
relatively small press units and can expand stepwise. Great and expensive technological changes, like e.g. totally replacing
well invested publication gravure plants, are not necessary. Existing presses, e.g. for web offset, can be adapted with limited
expenditure.
2 Contents
1 Introduction
2 Contents
3 Crucial Events
3.1 Concept
3.2 Realization
- formulating attempts - web offset test press - printing essay actions - collaboration team - prototype press
3.3 An end
- January 2003 - 3 additional printing essay actions - patent –
4 Results
4.1 Progressive Features of Fusible Ink
- 10 items of advantage - 4.2 Some Practical Details
4.2.1 - preparation of lab quantities - greater quantities – 10 g samples -
4.2.2 - flow properties -
4.2.3 - Metronic test printing unit - test printing details - lowering the ink setting speed -
- screen roller + chambered doctor blade -
4.2.4 - scumming - 4.2.5 - rub and blocking resistance -
4.3 Ink Formulation
- generally - inertness -
4.3.1 - polymers -
4.3.2 - resins -
4.3.3 - diluting agents -
4.3.4 - pigments - 4.3.5 - additives -
3 Copyright © Technische Universität Darmstadt, 2011
4.3.6 - optimum formulation - 4.4 Packaging Printing
- indirect letterpress printing on polyethylene - aluminum and plastic foils -
- gravure printing - hot seal resistance –
5 Some of the still unsettled details
5.1.1 - ink setting speed - 5.1.2 - storability -
5.1.3 - cheap black –
6 Selected Bibliography
7 Aspects
- web offset - sheet fed offset - newspaper printing - - novel universal press for any plate and paper type –
8 Continuation
9 Conclusion
3 Crucial Events
Some of the events are reported which were decisive for the course of the fusible ink development work and for its results.
3.1 Concept
Starting point for this r&d project was the published information that in the heatset web offset process only 1% of the energy
fed into the very expensively invested heatset drying equipment is used for evaporating the heatset oil, whereas 99% induce
problems and are wasted. To overcome this by making heatset drying basically dispensable arose the concept of using fusible
inks instead of heatset oil containing ones.
These inks should be solid, sufficiently hard, and chemically inert. They should melt in an acceptable narrow range near 60 to
65 °C, and their fuse should meet all rheological and printability requirements for perfect offset printing. Besides, any
disadvantages like those of ink film strength, practical handling, impacts on health or environment, etc. should be avoided.
Because parts of the printing press should be temperature adjusted to an - as moderately as possible - elevated temperature
(no “hot”-melt !) one should refrain from voluminous roller inking units and prefer the well-known short units. Therefore,
waterless offset plates should be used in the first stage.
3.2 Realization
In realizing this concept, very first ink formulating attempts were made with conventional binding agent compositions for
heatset web offset, but now without diluting agent. That failed.
Then, completely different binding agents according the hotmelt adhesives pattern, but directed towards properties
according the concept, were utilized for novel ink preparations. The first of them did already print in still provisional printing
attempts. And it happened surprisingly, that there was no scumming with waterless plates.
After this encouraging start, it was early in 2001 that a collaboration with the German printing press manufacturer Metronic
AG could be obtained. Metronic installed at once a web offset test press, web width 15 cm, for lab quantities of ink in one
of their factory buildings. The press had one short printing unit, some months later a second one was installed. Both were
4
basic models
separately fed
Using this ins
days, with ink
Thus, a broad
advantages a
progressively
We", - that w
motivated co
the organizat
In January 20
printing with
ink and press
3.3 An End
But it was jus
difficulties. T
construction
It happened t
receiver caus
January 2003
later it was d
Metronic kind
broad variety
Such kind of
from their pro
d by hoses fro
stallation, we
ks according t
d variety of bin
and disadvanta
y improving ink
was the determ
mmon endeav
tion of the form
003 we had at
h 4 (two times
s application a
d
st in that Janu
The newly appo
instantly but
that during th
ed a reduction
3. Later, the m
definitively term
dly allowed 3
y mentioned, w
printing was f
oduction prog
m nearby plac
could run man
the mentioned
nding materia
ages thereby le
k and print qu
mined and effic
vor with Micha
mer German in
ttained the sta
four) printing
at the Drupa 2
uary 2003 tha
ointed non-tec
t likewise the e
at time the Sc
n of the Schmi
money was not
minated.
3 additional pr
we strove to de
formerly prote
ram. They we
ced water oper
ny printing tes
d pattern. We t
ls and combin
earning featur
ualities.
Figure
ient collabora
ael Bender, Ge
nk manufactur
age for starting
g units, width
2004 exhibition
t this developm
chnical CRO (c
entire project.
hmidt Co. wer
idt payroll by w
provided for t
rinting essay
educe a prelim
ected by the E
re equipped w
rated thermos
sts in 2001 and
tried some mo
nations (see 4.
res, interrelatio
e 1, Printing Es
ation of Metron
eorg Thirase, a
rer Gebr. Schm
g the planned
30 cm. Schmi
n.
ment work en
chief restructu
re loosing thei
which, among
this project in
actions in 200
minary optimu
European Pate
Copyrigh
with temperatu
tats (see 4.2.3
d 2002 in five
ore than 500 d
3) could be pr
ons, and detai
ssay Action
nic, and in the
and Annette Le
midt GmbH.
construction o
dt and Metron
nded suddenly.
uring officer) d
ir autonomy (a
g others, G.Thi
his budget, th
03. Now, inste
um formulation
ent 0 790 893
t © Technisch
ure adjustable
3).
printing essa
ifferently form
ractically teste
ls of press, pri
e ink lab the ve
eister. This fou
of a prototype
nic had intende
. In that month
did not only st
and later on th
irase and A.Le
here was no ev
ead of continu
n from the hith
"Printing Proc
he Universität
cylinders, eac
ay actions, ea
mulated fusible
ed. We evaluat
inting, and ink
ery valuable, i
ur-strong team
e press for ind
ded to launch t
h Metronic go
top the planne
heir existence)
eister were dism
vidence of his
uing the resear
herto attained
cess".
Darmstadt, 20
ch of them bein
ch of several
e ink lab charg
ted their
k properties f
ngenious and
m worked with
dustrial web of
this novel fusib
ot into financia
ed prototype
). Their foreig
missed in that
support; and
rch with the
d manifold resu
011
ng
ges.
for
hin
ffset
ble
al
gn
t
still
ults.
5 Copyright © Technische Universität Darmstadt, 2011
4 Results
4.1 Progressive Features of Fusible Ink
By our development work the conceptional requirements (see 3.1) could be met stepwise but rather straight. Like common
with developments, the related details demanded relatively more efforts.
The result was a species of ink which differs from the traditional ones in a special binding agent composition without solvent
or oil and in its solid state. Its quality of being solid at ambient temperature and its defined flow properties in the moderately
heated ink train led immediately to several advantages over the traditional printing technique. Some further advantages
resulted additionally:
- The ink sets instantly - and that without drying equipment and energy supply.
- A high print quality is attainable,
because without solvent or oil, amongst others, less dot enlargement and no strike through,
less dependance on the type and printability of paper as well as on printing forme type,
with wide-area aspects (see 7, 4.3.3 par. 3).
- In operational pauses the residual ink can normally be left in the press without clearing and
cleaning (non-reactive ink)(see 4.3).
- Much more than marginal energy saving (see 3.1, 4.2.3 last par., 7).
- No emissions, no ignition hazard.
- No environment, health, or deinking problem.
- Easier and cleaner packing (e.g. in paper bags), storing, shipping, and handling of ink.
No leakages, blots, impurities.
No tight container/tank and pipe system needed.
The form of pourable granulate allows mechanical conveying (see 4.2.1 par.2, 4.3).
- Substantially reduced scumming tendency in waterless offset printing and plenty tolerance
for press temperature control (see 3.2, 4.2.4).
- Sufficient rub and blocking resistance like newspapers and gravure printed magazines
(see 4.2.5).
- Less investment and operation expenses.
6
4.2 Some P
4.2.1
For the lab p
other in a tin
compatibility
temperature
to get the hig
foil. After coo
were extensiv
Greater quan
Our test runs
no more than
dispersing, an
For simply pr
of thin alumi
identified by
drawdowns,
4.2.2
The ink flow
100sec-1
, 70°
80°C down to
at 75 °C.
Practical De
preparation of
n can at about
y and wettabili
adjustable thr
ghest possible
oling to ambie
vely controlled
antities can on
s in an extrude
n extrusion tec
nd finishing to
re-assessing di
num sheet. Th
hand, their tr
feasible on a h
w properties , b
°C ) and the so
o solidification
etails
f some few hu
t 170°C, and t
ity allowed to
ree roller mill,
but still fluid c
ent temperatur
d by rheomat (
ly be produced
er manufacture
chnique plus a
o pourable gra
ifferent bindin
heir rheologica
anslucency (re
hot plate, one
being controlle
olidification te
n. Additionally
ndred grams o
then the pigme
do it without
beginning at
consistency an
re it was peele
(4.2.2).
d by extrusion
er's shop succe
associated dosa
anulate/pellets
ng agent variat
al values could
egrettably not
could also use
ed by rheomat
emperature. Th
y instructive w
Figu
of ink, the bin
ent was stirred
a mechanical
about 70°C a
nd maximum s
ed off and cut
n technique lik
eeded at once
age the ink pro
s.
tions, 10g-sam
d be exactly m
yet transpare
e these 10g-sa
t, were in par
he latter was a
were the functio
ure 2, Spatula D
Copyrigh
nding agent co
d in, both sim
l disperser or s
and then empi
shearing. The
into pieces. -
ke the manufac
. But money fo
oduction can b
mples were ea
measured. Thei
ncy) by eviden
mples with an
rticular the vis
ascertained by
on viscosity vs
Drawdown
t © Technisch
omponents wer
mply by manua
suchlike. This
rically regulat
milled and fus
- The flow prop
cture of pigme
or something l
be run continu
sily fused and
r mechanical p
nce. For the ge
nd without stir
cosity (cone/p
y the function v
s. shear rate an
he Universität
re briefly disso
al stirring. The
charge was m
ted to a lower
sed charge wa
operties of the
ented plastic's
like this was n
uously i.e. dos
d mixed by han
properties wer
enerally advan
rred-in pigmen
plate 25 mm 1
viscosity vs. te
nd furthermor
Darmstadt, 20
olved in each
ir good
milled on a
temperature f
as spread on a
ink prepared
masterbatche
not granted. By
ing, mixing,
nd in small pan
re roughly
ntageous spatu
nt.
1°, rotative,
emperature fro
re viscosity val
011
for
s.
y
ns
ula
om
lues
7
4.2.3
Details of the
(as to the tem
Normally, we
and exception
Toray and ex
halftone wed
In this test pr
near 90°C, bo
sometimes no
achieved by i
In the test pri
thermostatica
fusing device
We put the in
accelerated b
overheated b
Future presse
doctor blade
the mentione
be furnished
become possi
The requirem
small, and a g
e Metronic tes
mperatures see
e printed on 60
nally on 49g/m
xceptionally th
dge + screened
rinting arrange
oth only to low
ot be really pe
ink formulatio
inting arrange
ally controlled
e. It was only f
nk pieces into
by hot-air gun.
by continuous h
es for industria
systems for do
ed minor ink se
with a therma
ible to lower t
ment for therm
good deal of h
st press printi
e also below).
0g/m² LWC pa
m² newsprint.
hose of Presstek
d image etc. R
ement, the pap
wer the ink se
erfectly covere
on means. Due
ement used, th
d. It should no
for these addit
the open (and
With this des
heating plus fr
al production
osing, and ext
etting slowdow
ally insulating
his uniform in
mal energy supp
heat will be ge
Figure 3, Prin
ting unit (3.2)
aper (Light We
Web speed in
k were used, b
Regular printin
per web was m
etting speed a
d at high web
to lack of tim
he screen rolle
ot only dose th
tional purpose
d readily clean
ign we could n
riction. So, exp
of printed pro
ruder type con
wn the whole
casing, being
nk train plus pr
ply is low beca
enerated by fri
nting Unit with
are shown in
eight Coated)
n our ink test r
both with usua
ng nip tempera
moderately pre
a little. Withou
speed.- In a p
me and money
ler + chamber
he ink but it sh
es that it worke
nable) doctor b
not dare more
perience with
oducts should h
nveyors for fee
printing unit c
ready for ope
rinting nip tem
ause the speci
iction in the fin
Copyrigh
h Short Inking U
this schema d
, as widely use
runs was gener
al test element
ature was near
e-warmed, and
ut this prelimin
project continu
we could how
ered doctor bla
hould addition
ed at a higher
blade chamber
e than short tim
long time run
have close tem
eding and fusi
could be adjus
ning and dism
mperature to a
fic heat capaci
nal production
t © Technisch
Unit
drawing
ed in heatset w
rally 200 or 30
ts, normally U
r 75°C.
d the impressi
nary makeshif
uation, this min
wever not realiz
lade could be h
nally serve as a
temperature t
r, where it was
me runs becau
ns was not gain
mperature adju
ng the ink. - B
sted to a unifo
mantling. After
about 65°C.
ity and the me
n run.
he Universität
web offset adv
00 m/min. No
UGRA 1982 wi
ion cylinder w
ft mode, the pr
inor slowdown
ze this alterat
heated but not
an ink entranc
than that of th
s heated and f
use it would be
ned.
ustable screen
By these impro
orm temperatu
r that, it would
elting enthalpy
Darmstadt, 20
vertising printi
ormally plates
th solid +
was adjusted up
rints would
n should be be
ion (5.1.1).
t cooled and
e and as an in
he printing nip
fused, sometim
ecome
roller plus
ovements and
ure. It could th
d prospectively
y of the ink ar
011
ing,
of
p to
etter
nk
p.
mes
by
hen
y
re
8 Copyright © Technische Universität Darmstadt, 2011
4.2.4
Knowingly, scumming is an inherent problem of waterless offset printing. Its more or less intense occurrence depends on the
design and state of press and plate - and not least on the ink and with it on its viscosity. Increasing viscosity decreases the
scumming tendency, but it also decreases the supple ink transfer and with it coverage, density, and halftone rendering.
Needed is a sufficient range with likewise good ink transfer and clean (unscummed) prints.
This range has been ascertained 2003 for the deduced kind of ink (3.3 par.3). For this, two series of it (the second one with a
lower resin concentration) were prepared with viscosity gradings by small variations of the binding component relations
within the formulation model (4.3). Under the test printing conditions (4.2.3) there began scumming at viscosities (4.2.2)
below 50 Pas and on the other hand reduced ink transfer with higher than 100 Pas. Thus, there is plenty tolerance for ink
viscosity and/or corresponding press temperature.
For comparison, we print tested 2003 a sample of a conventional ink, as industrially used for waterless offset newspaper
printing with short inking unit by which high quality prints were attained. For this industrial printing a press temperature of
22°C to 30°C was recommended. Its viscosity was 96 Pas under the conditions of item 4.2.2 but at 26°C instead of 70°C. With
test printing at various temperatures within the said range and with some other modifications of the printing conditions we
could not attain any print without both of the said print quality deficiencies, i.e. coincidentally scumming plus poor ink
transfer properties (tolerance less than zero). This can be explained by the simple printing conditions of our test press
(4.2.3) instead of the highly elaborate and low tolerance qualities of the said industrial one.
Thus, the rule becomes outdated that a narrow temperature tolerance is mandatory for waterless offset printing.
4.2.5
The rub and blocking resistance of prints, which were test printed 2003 with this kind of ink (4.3), proved the same level
like the usual offset printed newspapers and gravure printed magazines.
Various samples were rub-tested with the device of the Prüfbau Dr.-Ing Dürner GmbH at an ambient temperature.
The blocking tester used had 5 spring-loaded pistons which bore pressures of 2 1/2, 5, 10, 20, and 50 N/cm² on two LWC-
paper prints being placed there face-to face - 2 hours at 70°C. Only the highest load resulted faintly visible alterations of the
ink film. 40 N/cm² corresponds to a load of 250 kg on a DIN A4 (= 1/16 m²) paper sheet.
The rub and blocking resistance can be further improved by a subsequent treatment with a suitable aqueous varnish.
An outsider could doubt this good result in view of the ink melting range near 60°C to 65°C. But it is secured by the non-
stickiness and the reinforcing polymer content of the ink plus the absorptivity of the paper.
4.3 Ink Formulation
This fusible ink consists generally of 1.) Polymers, 2.) Resins, 3.) Diluting agents, 4.) Pigments, and 5.) Additives. Their
qualities and concentrations form a multiple-variable system of interdependencies. To tackle it, some intuition and ink
formulation experience are helpful. An issue is signified by our preliminary optimum (4.3.6).
The ink flow and printability properties can be altered and adjusted by varying the mass relation of the different polymers
and that of the polymer+resin to diluent.
Of course, this fusible ink must not contain any kind of hydrophilic or volatile component.
9 Copyright © Technische Universität Darmstadt, 2011
According to the concept (3.1) the fusible ink and with it the entire binding agent composition must be chemically inert, that
is to say free from reactive components, inclusive unsaturated hydrocarbon groups. Chemical reactivity would, among other
disadvantages, impair the storability, and impede that the ink could normally remain in pauses in the press and to be
repeatedly fused for additional running periods, and also the ease of cleaning. By this inertness, surfaces being wet by fused
ink can at any time be easily cleaned by wiping with liquid aliphatic hydrocarbons, e.g. white spirit (low aggressiveness,
with high flashpoint reduced fire hazard) (but caution with waterless offset plates !). The inertness is thoroughly
advantageous for publication and commercial printing. - But for packaging printing there exist disadvantages (4.4).
4.3.1
Polymers. A sufficiently great polymer content is one condition for the mechanical ink film strength necessary, and it
contributes to favorable flow properties.
When we tried a broad variety of binding materials and compositions, various ethylene-copolymers proved useful. Their
special aptitude depends greatly on their medium mole masses resp. rheological properties (e.g. melt flow indices), on their
melting temperatures, and last but not least on their relation polar/apolar in their basic monomer constitution. By relative
apolarity the non-stickiness is enhanced and by relative polarity the compatibility (compatibility in an amplified sense) and
the ink transfer and with it the coverage of the ink film. Considered as being relatively apolar is here the polyethylene mass
part of the molecule (also straight/branched chain). Considered as being relatively polar is here its vinyl-acetate, vinyl-
propionate, acrylate, maleic etc. mass part. Between the latter we did not find important differences for our purpose.
Therefore we confined ourselves to ethylene-vinylacetate-copolymers (EVAs) as relatively favorably available polymers. Out of
their various types the low molecular ones were preferred, and combining several of them was better than using but one.
Among them a modest part of a relatively higher molecular one improved the mechanical strength of the ink film.
4.3.2
Resins, having generally noticeably lower molecular masses than the polymers, do favorably influence the compatibility, the
viscosity, the melting temperature and the ink transfer properties of the fusible inks described. Here they must be hard and
free from oil portions, and notwithstanding have a lowest possible melting temperature, at least below 70°C, and in not too
broad a melting temperature range. They should be feasibly bright and they must be very compatible in the said binding
agent composition. Under these conditions, several different chemical constitutions were usable. Too much resin must be
avoided in the formulation because it would lead into the direction of stickiness, a drawback which is else readily avoided in
our kind of fusible ink.
We used the well suitable hydro carbon resins Escores (Exxon), without taking account of cheaper resins in our limited time.
4.3.3
Diluting agents are necessary to lower the melting temperature and the viscosity of the polymers and resins applied, and for
narrowing their melting range.
For them the following conditions exist: They must be very compatible with the other binding agent components. They must
not cause any softening or plasticizing effect. They must be solid and feasibly hard at ambient temperature, preferably
crystalline or pseudo crystalline. They should melt not higher than 55 °C and that in a narrow temperature range. They must
not contain components which are liquid at ambient temperature.
If these conditions are met fusible inks become obtainable whose transfer and setting properties are largely independent of
the formes and substrates used in a printing process. This is strongly contrary to traditional and present printing, in which
very different ink sorts are characterized by being diluted with organic or aqueous solvents, or oils, or radiation curable
10 Copyright © Technische Universität Darmstadt, 2011
monomers, and by being applied with different formes and substrates in different printing and ink setting processes for
different jobs in the production of printed products.
First choice for suitable diluting agents were hard waxes and waxy materials, waxy in its broader sense, and that rather
independent of their chemical constitution.
Among them paraffin waxes seemed principally suitable. But the immediately available of them which met most of the
conditions mentioned were not hard enough and they did contain too much residual oil. Polyolefin and Fischer-Tropsch-
Waxes seemed desirable. But we did not find low melting ones among them. The ester wax Okerin 5429 of Honeywell did
comply with the conditions. It was said to be cetyl-stearate. From then forward, we did not find the time for searching for
other and cheaper waxes. Surely exist applicable other ester waxes and fatty acid derivatives. Perhaps a saturated ( e.g.
hydrogenated) hard fat (triglyceride) may be quite suitable.
Too much wax does impair the mechanical ink film strength. Therefore it remains desirable to find basically other agents for
lowering viscosity and melting temperature. They should be much more effective also in low concentration, perhaps certain
chemically defined monomolecular organic substance, for getting more scope for formulation with polymers.
4.3.4
Pigments. Fusible ink development is predominantly directed at binding agents. The coloring agents for traditional inks are
normally suitable for fusible ones, as well, and known pigment application rules do also fit to them. Few exceptions are self-
explanatory.
In the course of our development work, the ink charges were generally pigmented with a phthalocyanine cyan. Only for
proving the multicolor printing - it was readily successful - in the mentioned printing essay actions (3.2) we simply replaced
the cyan by the usual magenta, and yellow pigments. Thereby needed flow property corrections caused no problem. Merely,
the ink flow was impaired when using high structure types of carbon black instead of low structure ones.
4.3.5
Additives. The beneficial use of additives with fusible inks does not differ from that with traditional ones.
4.3.6
Optimum formulation. The preliminary optimum - two exemplary preparations A and B, in which B has a greater portion of
higher viscous polymer and accordingly more wax - of fusible ink, as related 2003 to the Metronic test press (3.2 and 4.2.3),
is composed as follows (parts wt/wt)
A B A B
1a 13,8 8,8 3 26,0 30,8
1b 11,8 8,8 4 23,0 23,0
1c 9,9 13,9 5a 0,1 0,1
2 13,9 12,3 5b 1,5___ 1,3____
100,0 100,0
Table 1, Optimum Formulation
11 Copyright © Technische Universität Darmstadt, 2011
Solidifying range near 60°C, viscosity (4.2.2) near 66 Pas.
The components 1a, 1b, and 1c are ethylene vinylacetate copolymers (EVA) with the relations
E: VA 1a.) and 1c.) 72: 28, 1b.) 67: 33. 1a.) has the highest melt flow index (MFI) , i.e the relatively lowest melt viscosity,
1b.) a mid-MFI and 1c.) a relatively low MFI. 2.) is a bright and hard hydrocarbon resin. 3.) is a low melting but relatively
hard ester wax. 4.) is a well wettable phthalocyanine cyan pigment. 5a.) is an oleophilic coated very fine silicic acid
(reinforcing filler). 5b.) is a silicone oil.
1a) is Elvax 205 W (Dupont), 1b A) is Evatane 33-400 (Atofina), 1b B) is Elvax 140 W (Dupont), 1c) is Evatane 28-150
(Atofina), 2) is Escores 5340 (Exxon), 3) is Okerin 5429 (Honeywell), 4) is Heucoblau 515303 (Heubach), 5a) is Aerosil R
972 (Degussa (now Evonik)), 5b) is Adid 210 (Wacker).
The preparation is done according item 4.2.1 par.1. In it, 5b) is expediently mixed into the charge in the third milling
passage.
4.4 Packaging Printing
Our development was especially directed to offset on paper. But there were side-observations which opened some approach to
packaging printing.
In 1997 when we tried fusible ink provisionally on a letterpress proof press, it happened that a colleague initiated a short test
with indirect letterpress printing on small rigid cylindrical containers of polyethylene. In it, the very first of the inks
according the hotmelt adhesives' pattern (3.2) did really print and resulted strikingly good adherence, better than obtainable
with UV-curing ink.
When preparing the 10g-samples according 4.2.1 par.3, they could often only be loosened with difficulty from the small
aluminum pans, sometimes the adhesion was non-detachably fast.
Thus it was consequential to put casually webs of plastic (PET) and of coated and uncoated aluminum foil in the only
available press, the waterless web offset press (3.2 and 4.2.3). Well printed looking and firmly adherent prints were attained.
Some attempts to packaging gravure printing began 2003 on demand. The inks being formulated according the same
hotmelt origin pattern but containing more wax and being printed at 120°C instead of about 75°C resulted first gravure
prints.
Then, the German press manufacturer BHS (now Gallus Stanz- und Druckmaschinen GmbH) constructed a press for tests and
for limited production. With it they achieved developments in gravure printing on various foils, paper, and board, amongst
others with adapted cell shapes. They were successful, but it was abandoned because fusible ink was no longer available
(3.3).
Connected with the well looking prints and strikingly good adherence qualities there existed a basic disadvantage. According
to the concept (3.1), the ink and its ink film are chemically inert (4.3). That means good performance on paper, particularly
in publication and commercial printing. But with packaging, this inertness means poor resistance against organic solvents and
oils and additionally against heat. (The latter differs from good results on paper (4.1 /9, 4.2.5)).
12 Copyright © Technische Universität Darmstadt, 2011
To overcome this, a part of the binding agent combination (4.3) was replaced by hydroxyl groups containing constituents.
This does not impair the storability etc. (4.1, 4.3). When varnishing such a print with a two-component varnish containing di-
isocyanates this ink film got rather good hot seal resistance. For it, a very small amount of di-isocyanate did suffice. To avoid
the disadvantage of the varnish caused solvent usage in future a suitable di-isocyanate preparation could be applied without
solvent by inkjet, being aimed on the covered area portion of its OH-containing ink film.
5 Some of the Still Unsettled Details
In our development work various details have been left undone (3.3). Some of them are mentioned in the preceding items.
Still more is to be done on the steps from the present stage up to business (8).
Objects of the following section are detail tasks which we could so far not even begin to investigate.
5.1.1
As pointed out in 4.2.3, the target-oriented slow down of the ink setting speed, probably in the range of tenths to
hundredths of a second, is necessary to allow an appropriate design of a web offset press for industrial use. This could be
done for instance by partially replacing the preferred wax by a second one with a somewhat broader solidifying temperature
range.
The related careful adjustment might be supported by caloric and kinetic measurements. Simpler and without numerical
values could it be done by practical experiments with a modified spatula drawdown method. It needs a specially made twin
heating plate with two adjustable heat sources, one for up to about 120°C and the other up to about 60°C. Both are adjacently
placed, their interspace of perhaps 8 mm being filled with a mechanically solid and thermally insulating piece of material. On
its top side an even plane is formed by their tops and by the insulating piece. A sheet covering this plane should have an as
possible suitable thermal conductivity characteristic and upside an even and firm surface. On this surface the drawdown is
drawn from the warm to the cold part, passing a narrow border line. The distance where the formation of a perfect ink film
ends will give an indication for the solidification speed.
5.1.2
We secured the inertness and storability quality of fusible inks by several days heat treatment and by viscosity evaluation
before and afterwards. But the stated good durability can not apply without limitation. The influence of time, temperature,
air, humidity, sunlight, and microbial degradation should be quantified one day.
5.1.3
Developing a cheap black fusible ink seems promising. A suitable dark material should become its main binding component.
In regard to the requirements as compatibility, hardness, low solidifying temperature, no liquid, soft, or oily components
(4.3), it might not be easy to find a suitable by-product in the the chemical, petroleum, coal or fat processing industries, from
natural occurrence, or else.
Probably, its physical properties should be modified by some reinforcing polymer (4.3.1) and by diluting agent (4.3.3) or like,
all of them very compatible.... Carbon black can favorably act as blackening pigment and likewise as reinforcing and
adsorbing filler.
13 Copyright © Technische Universität Darmstadt, 2011
In the general application of such dark materials it is especially advantageous to liquefy them by heat and not by adding oil,
e.g. in street paving, in roof sealing, - or (!!) in print quality.
6 Selected Bibliography
Bremer, H. 1994 European Patent 0,790,893 (August 12, 1998)
Griebel, R. 1992 German Patent 4,205,636 (December 22, 1994)
Griebel. R. 1992 German Patent 4,205,713 (August 4, 1994)
Jones, W. 1937 U.S. Patent 2,147,651 (February 21, 1939)
Jones, W. 1938 U.S. Patent 2,264,315 (December 2, 1941)
Schepp, H. 1975 U.S. Patent 4,066,585 (January 3, 1978)
7 Aspects
Immediate aspects arise in the field of offset printing. Others can follow in a subsequent course of dealing with fusible inks.
Initial point and primary object of this r&d project is progress for the web offset process. In it, the advantages over heatset
are evident (3.1, 4.1).
Unnecessary become the whole investment and operating expenditures of the dryer installation, particularly oven, chill roll
assembly, web remoistening, and heating gas supply, as well as the prevention of condensate, ignition, explosion, and
emissions. The known disadvantages for the paper web, 4/5 of the entire (calculated 1999, press incl.) energy requirement,
and most of the CO2-exhaust are avoided.
Quality printing (gloss incl.) on substrates like coated, glazed, thin, or less smooth paper is possible.
Merely the very high gloss of heatset, as wanted for some advertising products, is not a feature of the fusible ink process. With
it, the print sets very fast and without the time and the conditions for leveling (and thus generating high gloss) in an oven
passage. Then, a subsequent treatment is needed for still more gloss.
In sheet fed offset printing with short inking unit, the main advantage may be the instant ink setting and the much cleaner
and more convenient ink handling. Also advantageous is that the inert ink can remain in the press in pauses and be
repeatedly warmed for printing operation. These advantages are particularly beneficial in office and digital printing. And due
to less scumming tendency, short inking units can be applied more frequently (4.2.4).
For newspaper printing an extensive general progress is imaginable.
Presently, coldset offset with damping is predominant. Beside that the the flexo process exists. With its short inking unit and
without damping, the presses are substantially less complicated in investment and operation. In spite of its advantages, the
flexo process is not widely introduced but remains reserved to a minority of users. That is why its presently applied aqueous
ink has a detrimental effect on used paper deinking and recycling.
The flexo press design and the flexo printing formes are largely suited for fusible ink. The design of the waterless offset
newspaper presses with their short inking unit, also in a minority, is quite similar in this respect. With fusible ink, at least the
14 Copyright © Technische Universität Darmstadt, 2011
deinking problem of flexo and the scumming tendency of this kind of offset would be eliminated. Among other advantages,
both could then not only print on newsprint but also on coated, calendered, or thin paper for acquiring additional (heatset)
jobs.
This fusible ink can likewise print from flexo and from waterless offset plates. It can also print from letterpress formes. One
reason for making this process obsolete were the dot fringes. The shoulders of the dots etc. were wet with ink. This ink
portion was squeezed on the paper additionally to that from the forme tops, and this unwanted ink and oil (!) surplus caused
smearing, excessive dot enlargement, print-through and set-off. Fusible ink would not eliminate the dot fringes but their
adverse effect.
Flexographic and letterpress formes are both of the relief type, originally the former soft-elastic (rubber), the latter hard-rigid
(metal). This difference diminished with the introduction of plastic for printing formes. With it, by the relatively stiffer formes
for flexo and by the relatively more elastic for letterpress the print quality of both got improved. With fusible ink can be
printed from both these formes and also from an intermediate stage without a difference of elasticity.
Even the use of lithographic plates could be made feasible, if the extrusion technique would ingeniously help to it. Then the
extruder type ink conveyor (4.2.3 penultimate paragraph) could get an additional entrance for damping fluid, and the
instable w/o emulsion necessary could be inline generated by extruder shearing. (Who else makes emulsions by batteries of
rollers ?)
Thus, in a later stage a novel universal press for newspapers and more might become imaginable.
In it, one sole fusible ink per printing unit is permanently applied, i.e. remains there without clearing...(4.1, 4.3). According
to the technical and economical optimum and to the upcoming next job, e.g. newspapers, magazines, phone or railway
directories, commercial print works, etc., any plate, relief or planographic (optional blanket cylinder), and any paper type
(4.3.3) could be deliberately chosen.,
8 Continuation
A continuation of our left and abandoned (3.3) development work is necessary to realize the mentioned advantages and
aspects fully.
Fusible ink was welcomed by technically oriented experts when they became aware of it. But the financially oriented supreme
managements disliked to consider its potential, presumably because an instant or short-term investment return could not be
expected.
Nowadays, saving energy, avoiding emissions, and gaining a lead or at least keeping pace in relation to competitors became
increasingly important.
The technical conditions for resuming the project are favorable: Short inking units, temperature control of printing cylinders,
and the extrusion + dosage technique do exist. How to formulate inks which do really print, as well as additional results,
experiences, and indications are disclosed here.
I do not know any obstacle against a continuation by a basic patent.
Fusible preparations are common use with adhesives, some paint, non impact printing etc.,
why not in the production of printed products !
Thus it is promising to continue anywhere on the globe towards a rewarding progress.
15 Copyright © Technische Universität Darmstadt, 2011
Necessary are the collaboration of an ink and a press manufacturer, latest from the development phase 2. - The entire
development from its concept up to business can be roughly subdivided into three phases:
1.) Overall composition and application of fusible ink. 2.) Construction and demonstration of a functional model or a
prototype press, its ink, its operation, and its prints. 3.) Gradational business introduction.
Phase 1 needs an established ink lab with a small team and an opportunity of using a test press and an extruder. If the said
collaboration does already exist in the phase 1, it can likewise be used for investigating details of press design and operation.
We could do so, and thus phase 1 has for the most part been accomplished. For continuing it, one should initially get familiar
with the formulation of this kind of ink to adapt it to the then available components and to modify and improve it.
Phase 2 means assembling existing machine elements to a relatively small web offset press (or only a sheet fed press),
adapting the ink to it, and demonstrating their operation and results. If the said collaboration does not exist from phase 1,
one could arouse the interest of press manufacturers to enter phase 2 by impressively presenting the results of phase 1.
Phase 3 might be performed according the then actual conditions.
The expenses for phase 1 are small and those for phase 2 are limited. It will be not earlier than during phase 3, when
relatively greater expenses for the stages of business implementation will become effective step by step pursuant a raising
customers' demand.
9 Conclusion
Fusible ink is no mere proposal. It became a realistic technique. It needs continuation to become an item of real benefit and a
key to progress in print technology.
Contact
Dr. Hans Bremer
bremer.hans@web.de
Reference
www.idd.tu-darmstadt.de
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